Microscopic Many-Body Theory of Atomic Bose Gases near a Feshbach Resonance
Publication date
2003
Authors
Duine, R.A.
Stoof, H.T.C.
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DOI
Document Type
Article
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Abstract
A Feshbach resonance in the s-wave scattering length occurs if the energy of
the two atoms in the incoming open channel is close to the energy of a
bound state in a coupled closed channel. Starting from the microscopic
Hamiltonian that describes this situation, we derive the effective
atom–molecule theory for a Bose gas near a Feshbach resonance. In order to
take into account all two-body processes, we have to dress the bare
couplings of the atom–molecule model with ladder diagrams. This results in
a quantum field theory that exactly reproduces the scattering amplitude of
the atoms and the bound-state energy of the molecules. Since these
properties are incorporated at the quantum level, the theory can be applied
both above and below the critical temperature of the gas. Moreover, making
use of the true interatomic potentials ensures that no divergences are
encountered at any stage of the calculation. We also present the mean-field
theory for the Bose–Einstein condensed phase of the gas.